Membrane Bioreactor System Using Reciprocating Membrane

ABSTRACT

The present invention relates to membrane bioreactor (“MBR”) system that includes a mechanical membrane reciprocation system to reduce or eliminate membrane fouling. The disclosed MBR system can be operated with higher flux and lower fouling than MBR systems using air scouring. Furthermore the system can remove nitrogen and phosphorous with one RAS and one or no internal recirculation line. The membrane can be reciprocated by a low RPM motor connected to a pulley via belt to rotate rotor to convert rotational motion into reciprocating motion of membrane. Various mechanical means can also be employed to create the reciprocating motion.

RELATED APPLICATION DATA

This application claims priority to co-pending application Ser. No. 61/711,081 filed on Oct. 8, 2012 and entitled “Vibration Membrane Bioreactor System Using Reciprocating Motion To Treat Wastewater.” The contents of this co-pending application are fully incorporated herein.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to a membrane bioreactor (“MBR”) system to treat wastewater. More particularly, the present invention relates to a MBR system that employs a repetitive back and forth motion (hereafter called the “reciprocating motion” or “reciprocation”) of a submerged membrane to increase filtration and nutrients removal efficiencies instead of membrane air scouring which is commonly utilized in submerged MBR.

2. Description of the Background Art

The background art contains several examples of MBR systems. These systems utilize biological treatment processes (e.g. activated sludge processes) to remove contaminants from wastewater. Several modified activated sludge processes can be used alone or in series for improved removal of nutrients in the MBR. Known MBR systems also use low pressure microfiltration (MF) or ultrafiltration (UF) membranes as a physical barrier for a complete solid-liquid separation. The UF or MF membranes can be submerged in a bioreactor or external to the bioreactor. Submerged membranes are typically installed in an aerobic bioreactor or a separate membrane tank. Membrane air scouring is of utmost importance in submerged MBR operation to prevent severe and rapid membrane fouling. By way of these known techniques, MBR systems can achieve secondary and tertiary wastewater treatment.

One advantage of known MBR systems is the direct production of tertiary quality effluent with the treatment of domestic or industrial wastewater. Another reason for the growing interest in MBR technology is its smaller footprint compared to conventional treatment processes. For example, using conventional MBR systems, a treatment plant could potentially double its capacity without increasing its overall footprint. MBR technology is not only limited to domestic wastewater, but it can also be applied to treat industrial wastewater for reuse.

An example of an MBR system is disclosed in U.S. Pat. No. 4,867,883 to Daigger. This reference discloses a high-rate biological waste water treatment process for removing organic matter, phosphorus and nitrogen nutrients from municipal waste water. A further MBR system is disclosed is U.S. Pat. No. 8,287,733 to Nick et al. It discloses a system utilizing first and second anoxic basins and first and second aerobic basins. Also disclosed is the use of a membrane chamber for housing a plurality of membrane tanks.

One common drawback of known MBR systems is membrane fouling. This occurs when soluble and particulate materials accumulate on the membrane surface. When such fouling occurs, there is either a marked decline in permeate passing through the membrane or an increase in the transmembrane pressure. In either event, the result is a dramatic reduction in system performance. Membrane fouling is especially problematic in MBR systems given that they generally operate with higher mixed liquor suspended solids (“MLSS”).

One solution to membrane fouling is air scouring. Vigorous air scouring allows for stable flux operation without rapid and permanent fouling and especially cake layer buildup. Given the higher MLSS concentrations at which MBR systems operate, frequent maintenance cleanings and out of tank cleanings are also important to maintain membrane performance in terms of fouling and permeability. Air scouring is not optimal as it is energy intensive. In MBR systems energy consumption is considerably higher than conventional activated sludge systems due to the additional air scouring for the membrane.

Thus, there exists a need in the art for improved MBR systems that eliminate or reduce membrane fouling and that do not rely upon air scouring. The present invention is aimed at fulfilling these and other needs in the art.

SUMMARY OF THE INVENTION

It is therefore one of the objectives of this invention to reduce or eliminate membrane fouling in an MBR system.

It is a further object of this invention to provide a MBR system that does not utilize membrane air scouring.

It is also one of the objectives of this invention to reduce or eliminate the presence of dissolved oxygen in return activated sludge (RAS) by not utilizing air scouring in membrane tank, thereby permitting the activated sludge to be returned from a membrane tank to an anoxic or anaerobic treatment tank.

It is still yet another object of this invention to operate MBRs with higher efficiencies in membrane filtration and biological nutrients removal via the reciprocation of a membrane.

The foregoing has outlined rather broadly the more pertinent and important features of the present invention in order that the detailed description of the invention that follows may be better understood so that the present contribution to the art can be more fully appreciated. Additional features of the invention will be described hereinafter which form the subject of the claims of the invention. It should be appreciated by those skilled in the art that the conception and the specific embodiment disclosed may be readily utilized as a basis for modifying or designing other structures for carrying out the same purposes of the present invention. It should also be realized by those skilled in the art that such equivalent constructions do not depart from the spirit and scope of the invention as set forth in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

For a fuller understanding of the nature and objects of the invention, reference should be had to the following detailed description taken in connection with the accompanying drawings in which:

FIG. 1 is a general process diagram illustrating the MBR system of the present invention.

FIG. 2 is a general embodiment of the reciprocation apparatus of the present invention.

FIG. 3 is a detailed view of an alternative embodiment of the reciprocation apparatus.

FIGS. 4-12 are process diagrams illustrating various alternative MBR processes of the present invention.

Similar reference characters refer to similar parts throughout the several views of the drawings.

PARTS LIST 10 Influent 20 Mixed Liquor Flow 21 Anaerobic to Anoxic Flow 22 Anoxic to Aerobic Flow 23 Aerobic to Membrane Tank Flow 24 Anoxic to Anaerobic Flow 25 Anaerobic to Aerobic Flow 30 Activated Sludge Return 31 Activated Sludge Return (Membrane Tank to Anoxic) 32 Internal Recirculation (Anoxic to Anaerobic) 33 Activated Sludge Return (Membrane Tank to Anaerobic) 34 Internal Recirculation (Aerobic to Anoxic) 40 Effluent 50 Biological Treatment Train 51 Anaerobic Tank 52 Anoxic Tank 53 Aerobic Tank 60 Membrane Tank 70 Submerged Membrane, membrane cassette 80 Reciprocation Apparatus 90 Sliding Frame 91 Linear Bearing with Pillow Block 92 Sliding Rail 93 Membrane Cassette Connection Point 94 Dampener 100 Rotor 101 Pulley 102 Belt 103 Low RPM motor 110 Shaft

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The present invention relates to membrane bioreactor (“MBR”) system that includes a mechanical apparatus for reciprocating a membrane cage (or membrane cassettes) back and forth. The apparatus eliminates the use of air scouring. Repetitive reciprocation of the membrane cage/cassette creates an inertia force acting on the membrane fibers, which shakes foulants off from the membrane surface. The system includes a membrane cage/cassette containing membrane modules that are submerged in either an aerobic tank or a separate membrane tank. The membrane cage/cassette can be mechanically reciprocated via reciprocation apparatus, which enable the disclosed MBR system to be operated with higher flux and lower fouling than MBR systems using air scoring. Various mechanical means can be employed to create the reciprocating motion. The various details of the present invention, and the manner in which they interrelate, are described in greater detail hereinafter.

FIG. 1 illustrates the basic components of the disclosed vibration MBR system. The system includes a biological treatment train 50 for receiving influent 10 to be processed. Various anaerobic, anoxic, and aerobic biological treatment processes can be carried out within treatment train 50. Mixed liquor 20 from treatment train 50 is then passed into membrane tank 60. Membrane tank 60 includes a submerged membrane 70 (or a series of membranes 70). Membrane(s) 70 may be, for example, a low pressure microfiltration (MF) or ultrafiltration (UF) membrane used as a physical barrier for a complete solid-liquid separation. Membrane cage/cassette 70 is mechanically interconnected to a reciprocation apparatus 80. In accordance with the invention, reciprocation apparatus 80 is used in reciprocating membrane 70. Reciprocation apparatus 80, in one non-limiting embodiment, uses a mechanical device for converting rotational motion into reciprocating motion. Filtration through membrane 70 in membrane tank 60 produces effluent 40. Membrane 70 may be continually reciprocated during filtration. Alternatively, membrane 70 can be selectively reciprocated as need to eliminate fouling. A portion of the activated sludge 30 (i.e. return activated sludge or “RAS”) goes back to biological treatment train 50 to maintain a sludge concentration within train 50.

FIG. 2 illustrates a general embodiment of the reciprocation apparatus 80. Membrane cassette 70 can be connected to a sliding frame 90. A motorized rotor 100 is connected to a sliding frame 90 via shaft 110. The depicted apparatus 80 thereby converts the rotational motion of rotor 100 into the reciprocating motion of the sliding frame 90. The frequency of reciprocation will be dictated by the speed at which rotor 100 is rotated.

An alternative embodiment of such an apparatus is depicted in FIG. 3 and includes a low RPM motor 103 connected to a pulley 101 via belt 102 to rotate rotor 100 to convert rotational motion into reciprocating motion of sliding frame 90 through a shaft 110. Shock load due to reciprocating motion can be reduced by dampener 94 in between sliding frame 90 and shaft 110. Sliding frame 90 can move along sliding rail 92 with linear bearing and pillow block 91 supports (FIG. 3). There are many different types of mechanical equipment that can provide the required reciprocal motion. Those of ordinary skill in the art will appreciate other suitable mechanical devices after considering the invention.

Various alternative embodiments of the present process invention are described in connection with FIGS. 4-12. With regard to FIG. 4, the system consists of a series of biological treatment tanks. These include anaerobic treatment tank 51, anoxic treatment tank 52, aerobic treatment tank 53, and membrane tank 60. The membrane 70 is submerged within membrane tank 60 and can is reciprocated by reciprocation apparatus 80.

The anaerobic treatment tank 51 receives influent 10 to be treated. Thereafter anaerobic treatment tank 51 biologically treats the influent in the absence of dissolved oxygen to release phosphorous for luxury uptake in the following aerobic conditions. In anoxic tank 52 the wastewater is denitrified in oxygen-depleted conditions. Dissolved oxygen is excluded from anoxic tank 52, although chemically bound oxygen may be present. Nitrification and luxury phosphorous uptake occur in the Aerobic treatment tank 53 in the presence of dissolved oxygen. Filtration in the membrane tank 60 produces effluent 40.

There are two recirculation lines for the activated sludge. A line 31 delivers return activated sludge (or “RAS”) from membrane tank 60 to anoxic tank 52. Additionally, an internal recycle line 32 delivers a portion of the activated sludge from anoxic tank 52 to anaerobic tank 51 to maintain mixed liquor suspended solids (or “MLSS”). In this invention, RAS takes two roles in conventional activated sludge or MBR processes. In prior art systems, the return flow of activated sludge from membrane tank contains dissolved oxygen (“DO”). Thus, in prior art systems, the activated sludge from the membrane tank could not be returned to the anoxic 52 or anaerobic 51 tanks due to the high amounts of dissolved oxygen effects on denitrification or phosphorous release. However, with regard the present invention, since physical membrane reciprocation is utilized instead of vigorous air bubbling, the DO in the RAS is minimal compared to conventional MBR. Therefore, only one sludge return line is required for both sludge and nitrate return in the present invention.

The system depicted in FIG. 5 includes anoxic 52 and aerobic 53 treatment tanks which is similar to the well-known Modified Ludzack and Ettinger (MLE) process. As described above, RAS 31 goes to anoxic tank 52 directly from membrane tank 60 for nitrate and sludge return in this invention. FIG. 6 represents another embodiment which consists of same reactors depicted in FIG. 4. However, return activated sludge 33 goes to anaerobic 51 treatment tank and an internal recycle 34 is made in between aerobic 53 and anoxic 52 tanks. FIG. 7 illustrates an embodiment similar to the process described in FIG. 6. However, there is no internal recirculation and the RAS goes to the anoxic tank where denitrification occurred. FIGS. 8, 9, 10 and 11 are modified systems depicted in FIGS. 4, 5, 6 and 7 respectively. The difference is in the existence of the membrane tank. The systems in FIGS. 4-7 have a separate membrane tank 60, but the systems in FIGS. 8-11 do not have a separate membrane tank 60. Namely, tanks 53 in FIGS. 8-11 function as both a membrane tank and as bioreactor. FIG. 12 shows further example of the processes developed in this invention which consists of simplest reactor configurations. Reciprocating membrane is submerged in a single bioreactor where both biological removal and membrane separation occur. The reactor can be aerated tank, pond or sequencing batch reactor (SBR) where aerobic and anoxic conditions are made in cyclic sequence.

The present disclosure includes that contained in the appended claims, as well as that of the foregoing description. Although this invention has been described in its preferred form with a certain degree of particularity, it is understood that the present disclosure of the preferred form has been made only by way of example and that numerous changes in the details of construction and the combination and arrangement of parts may be resorted to without departing from the spirit and scope of the invention. 

What is claimed is:
 1. A membrane reciprocation system comprising: a submerged membrane; and means for reciprocating the submerged membrane, whereby the reciprocation reduces membrane fouling.
 2. Reciprocating membrane bioreactor system comprising: a biological treatment train (50) for receiving influent (10) to be treated, the biological treatment train (50) producing treated wastewater; a membrane tank (60) housing a membrane (70), the treated wastewater from the biological treatment train (50) being filtered through the membrane (70) to produce effluent (40); a reciprocation apparatus (80) for reciprocating the membrane (70), the reciprocation reducing fouling on the membrane (70) and providing oxygen depleted conditions in the membrane tank (60).
 3. The system as described in claim 2 wherein the reciprocation apparatus (80) includes a rotor (100) that is interconnected to a sliding frame (90) via a shaft (110), the sliding frame (90) interconnected with the membrane (70), and wherein reciprocating the sliding frame (90) reciprocates the membrane (70).
 4. The system as described in claim 2 wherein the reciprocation apparatus (80) further comprises a low RPM motor (103) connected to a pulley (101) via a belt (102) to rotate a rotor (100) and thereby convert rotational motion into reciprocating motion of a sliding frame (90) through a shaft (110).
 5. The system as described in claim 3 wherein shock load due to reciprocating motion can be reduced by a dampener (94) in between sliding frame (90) and shaft (110), and wherein sliding frame (90) can move along sliding rails with linear bearings and pillow block (91) supports.
 6. The system as described in claim 4 wherein shock load due to reciprocating motion can be reduced by a dampener (94) in between sliding frame (90) and shaft (110), and wherein sliding frame (90) can move along sliding rails with linear bearings and pillow block (91) supports.
 7. The reciprocating membrane bioreactor system as described in claim 2 wherein the biological treatment train comprises: an anaerobic treatment tank (51) for biologically treating the influent in the absence of dissolved oxygen; an anoxic treatment tank (52) for denitrifying the treated wastewater under oxygen-depleted conditions; an aerobic treatment tank (53) for biologically treating the wastewater in the presence of dissolved oxygen; and an membrane tank (60) for producing effluent through membranes (70) reciprocated repetitively via reciprocation apparatus (80)
 8. The membrane bioreactor as described in claim 7 further comprising an activated sludge return line (31) for delivering the activated sludge from the membrane tank (60) to the anoxic treatment tank (52) and an internal recirculation line (32) from anoxic tank (52) to anaerobic tank (51).
 9. The membrane bioreactor as described in claim 7 further comprising an activated sludge return line (33) for delivering the activated sludge from the membrane tank (60) to the anaerobic treatment tank (51) and an internal recirculation line (34) from aerobic tank (53) to anoxic tank (52).
 10. The membrane bioreactor as described in claim 7 further comprising an activated sludge return line (31) for delivering the activated sludge from the membrane tank (60) to the anoxic treatment tank (52).
 11. The reciprocating membrane bioreactor system as described in claim 2 wherein the biological treatment train comprises: an anoxic treatment tank (52) for denitrifying the treated wastewater under oxygen-depleted conditions; an aerobic treatment tank (53) for biologically treating the wastewater in the presence of dissolved oxygen; and a membrane tank (60) for producing effluent through membranes (70) reciprocated repetitively via reciprocation apparatus (80).
 12. The membrane bioreactor as described in claim 11 further comprising an activated sludge return line (31) delivers the activated sludge from the membrane tank (60) to the anoxic treatment tank (52).
 13. A sequencing batch reactor eliminating a settling cycle and utilizing the mechanical membrane reciprocation system described in claim
 1. 